[0001] The present invention relates to an aluminum alloy sheet for use in press forming
and a method of manufacturing the same, more particularly, to an aluminum alloy sheet
suitable for use in an automobile body, exhibiting excellent bake hardening property,
even if baking is performed at a low temperature in the range of 120 to 180°C for
a short period of time of 5 to 40 minutes.
[0002] The Patent Abstracts of Japan, Vol. 17, No. 236 (C-1057), May 13, 1993, relating
to JP-A-04365834, discloses an aluminum alloy sheet for press forming. The composition
comprises 1.5 to 3.8 percent by weight Mg, 0.25 to 3.0 percent by weight Cu, 0.15
to 0.76 percent by weight Si, 0.03 to 0.25 percent by weight Fe, 0.005 to 0.15 percent
by weight Ti, 0.0002 to 0.05 percent by weight B and a balance of aluminum. The alloy
sheet is prepared by subjecting an ingot of the aluminum alloy to homogenizing at
450°C to 580°C, forming this ingot to a desired thickness by hot rolling and cold
rolling and subjecting the resultant sheet to a heat treatment.
[0003] The Patent Abstracts of Japan, Vol. 14, No. 134, (C-0701), March 14, 1990, relating
to JP-A-02008353, discloses the manufacture of an aluminum alloy for use in press
forming. The essential components of the alloy include 3.0 to 5.0 percent by weight
Mg, 0.06 to 0.6 percent by weight Zn and 0.3 to 2.0 percent by weight Cu with a balance
of aluminum. The composition further includes at least one of Mn, Cr, Ti and B.
[0004] The Patent Abstracts of Japan, Vol. 17, No. 124 (C-1035), March 16, 1993, relating
to JP-A-04304339, discloses an aluminum alloy sheet for use in press forming. The
alloy composition includes 1.5 to 8.0 percent by weight Mg, 0.25 to 3.0 percent by
weight Cu, 0.02 to 0.15 percent by weight Si, 0.03 to 0.25 percent by weight Fe, 0.005
to 0.15 percent by weight Ti, 0.0002 to 0.05 percent by weight B, 0.10 percent by
weight Zn and a balance of aluminum. The Mg and Cu are present in a prescribed ratio
of their respective amounts and the formed crystal structure is such that the average
aspect ratio of the crystalline grains is regulated to be less than 1.3.
[0005] A conventional surface-treated cold-rolled steel sheet has frequently been used as
a sheet material for automobile body panel. In recent years, however, for the purpose
of reducing fuel consumption, a light-weight automobile body panel material has been
demanded. To satisfy the demand, aluminum alloy sheets have begun to be used for the
automobile body panel.
[0006] Nowadays, manufacturers in press forming of panel sheets are requesting that the
material not only have low yield strength until being subjected to press forming so
as to provide a satisfactory shape-retaining property, see Jidosha Gijyutu (Automobile
Technology), Vol. 45, No. 6 (1991), 45, but also have a property such that strength
thereof can improved during paint baking to provide satisfactory formability of deep
drawing and overhang, and dent resistance.
[0007] Under these circumstances, an attempt has been made in which the strength of the
material was improved by adding Cu and Zn to a non-heat treated type, Aℓ-M based alloy
which has superior formability to other aluminum alloys. As a result, an Aℓ-Mg-Cu
alloy (Jpn. Pat. Appln. KOKAI Publication JP-A-57-120648 and JP-A-1-225738), an Aℓ-Mg-Cu-Zn
alloy (Jpn. Pat. Appln. KOKAI Publication JP-A-53-103914), and the like have been
developed. These alloy sheets are superior to an Aℓ-Mg-Si alloy sheet but inferior
to a conventional surface-treated cold-rolled steel sheet in formability, and exhibit
a poor shape-retaining property since the alloy sheets have high strength prior to
being press formed. In addition, the degree of hardening obtained by paint baking
is not sufficient, and the degree of hardening is low only to prevent work hardening
value obtained by press-forming from lowering. In Jpn. Pat. Appln. KOKAI Publication
JP-A-57-120648, an attempt has been made to improve the strength at the time of the
paint baking by precipitating an Aℓ-Cu-Mg compound; however, the results have not
been satisfactory. Since the effect of Si in improving bake hardening was not yet
discovered at the time the aforementioned application was made, Si was limited to
a low level.
[0008] A conventional 5052 material is used in the automobile body panel. Although it exhibits
a superior shape-retaining property owning to low yield strength prior to being subjected
to press forming, 5052-0 is inferior in dent resistance since satisfactory hardness
cannot be provided by paint baking.
[0009] The above mentioned Aℓ-Mg-Cu or Aℓ-Mg-cu-zn alloys have a common disadvantage in
that the alloys exhibit secular change in the strength prior to press forming because
natural aging starts right after the final heat treatment ["Report of 31st light metal
Annual Symposium", Sumi-kei Giho (Sumitomo Light Metals Technical Report), Vol. 32,
No.1 (1991), 20, page 31)]. Therefore, it is necessary to control timing of the manufacturing
raw material and heat treatment, and a period of time from the heat treatment to press
forming.
[0010] One technique of suppressing the secular change in the strength by natural aging
is provided by Jpn. Pat. Appln. KOKAI Publication JP-A-2-47234, which discloses that
natural aging of the Aℓ-Mg-cu-zn alloy is suppressed by reducing a content of Zn,
which has a significant effect on natural aging.
[0011] Nevertheless, heretofore, there have been no alloy which provide satisfactory bake
hardening, shape-retaining property, and natural aging retardation, even though they
may have excellent formability relatively close to that of steel.
[0012] The present invention has been made in view of the above circumstances. An object
of the present invention is to provide an aluminum alloy sheet for use in press forming,
having excellent bake hardening property by baking at low temperatures for a short
period of time and a method of manufacturing the same.
[0013] Another object of the present invention is to provide an aluminum alloy sheet fcr
use in press forming, exhibiting no secular change in strength prior to press forming
owing to low strength prior to being subjected to press forming and a natural aging
retardation property.
[0014] According to the present invention, there is provided an aluminum alloy sheet for
use in press forming, as defined in claim 1.
[0015] According to the present invention, there is also provided a method of manufacturing
an aluminum alloy sheet for use in press forming as defined in claim 3.
[0016] According to one embodiment, the method includes subjecting the stock to an intermediate
tempering treatment including heating the ingot up to a range of 500 to 580°C at a
heating rate of 3°C/second or more, keeping it at the temperature reached for 0 to
60 seconds, and cooling it to 100°C at a cooling rate of 2°C/second or more.
[0017] This invention can be more fully understood from the following detailed description
of embodiments when taken in conjunction with the accompanying drawings, in which:
Fig. 1 is a photograph showing a crystal structure of the aluminum alloy sheet according
to one embodiment of the present invention;
Fig. 2 is a photograph showing the metalographic structure of the aluminum alloy sheet
according to the embodiment;
Fig. 3 is a graph showing the effect of Mg and Cu on streak generation corresponding
to a modulated structure of the Aℓ-cu-Mg system compound in an electron beam diffraction
grating image;
Fig. 4 is a graph showing the effect of Si on the degree of bake hardening;
Fig. 5 is a graph showing the effect of Si on the degree of bake hardening and on
the degree of natural aging;
Fig. 6 is a graph showing the effect of Sn on natural aging;
Fig. 7 is a graph showing the effect of a rolling rate of the rolling treatment following
the intermediate tempering treatment on the degree of bake hardening; and
Fig. 8 is a graph showing the relationship between baking temperature and Vicker's
hardness after baking treatment, and between baking time and the Vicker's hardness.
[0018] The present inventors have made extensive studies with a view toward attaining the
above mentioned objects. As a result, they found that sufficient bake hardening can
be obtained in an Aℓ-Mg-Cu alloy, when generation of a GPB zone which is a modulated
structure observed prior to precipitating an S' phase made of an Aℓ-Cu-Mg compound
is promoted and a streak is observed in an electron diffraction pattern thereof. To
be more specific, if streaks indicating the presence of a modulated structure are
observed in its diffraction pattern when it is baked at a temperature of 120 to 180°C
for a time period of 5 to 40 minutes, the bake hardening after the baking at low temperature
for a short period of time of above ranges may be excellent. The present invention
was made based on the above mentioned finding and provides an aluminum alloy sheet
for use in press forming, having excellent property of hardening by baking at low
temperature for a short period of time, the aluminum alloy sheet which comprises an
Si-containing Aℓ-Mg-Cu alloy, and streaks are observed in its electron diffraction
pattern when it is baked at a temperature of 120 to 180°C for 5 to 40 minutes, the
streaks indicating the presence of a modulated structure of an Aℓ-cu-Mg compound.
[0019] The above mentioned streaks can be obtained by limiting contents of Cu and Mg of
the Aℓ-Mg-Cu alloy to a specific range and adding a certain amount of Si. To be more
specific, the streaks are obtained when the alloy essentially consists of 1.5 to 3.5%
by weight of Mg, 0.3 to 1.0% by weight of Cu, 0.05 to 0.6% by weight of Si, and the
balance of Aℓ and inevitable impurities, and the ratio of Mg/Cu is in the range of
2 to 7.
[0020] Fig. 1 shows an example of the electron diffraction pattern of the modulated structure,
which is very thin layers or zones and appears prior to the S' phase as the precipitation
phase of Aℓ-cu-Mg compound. Fig. 1 shows Aℓ (100) diffraction pattern. Streaks around
the reciprocal lattice image of the Aℓ-cu-Mg compound was pointed out by an arrow.
Fig. 2 is an electron beam transmission image, however, the modulated structure cannot
be observed at sites corresponding to those shown in Fig. 1. The results indicate
that the above mentioned modulated structure is too fine to be observed in the electron
transmission image. Therefore, the modulated structure is unlike precipitates. The
fine structure contributes to remarkable improvement of strength, thereby obtaining
an aluminum alloy sheet exhibiting the bake hardening.
[0021] To retard natural aging of the Aℓ-Mg-Cu system alloy, the alloy composition includes
at least one element selected from the group consisting of 0.01 to 0.50% by weight
of Sn, 0.01 to 0.50% by weight of Cd, and 0.01 to 0.50% by weight of In, in addition
to the above mentioned chemical composition based on the Aℓ-Mg-Cu system alloy containing
Si. An aluminium alloy sheet which is hardened by baking is accompanied by the natural
aging problem, which is a property that increases the hardness when it is allowed
to stand still at room temperature. However, the natural aging can be retarded such
that the effect of the natural aging is substantially absence by adding at least one
element selected from the above mentioned group.
[0022] Optionally at least one additional element selected from the group consisting of
0.03 to 0.50% by weight of Fe, 0.005 to 0.15% by weight of Ti, 0.0002 to 0.05% by
weight of B, 0.01 to 0.50% by weight of Mn, 0.01 to 0.15% by weight of Cr, 0.01 to
0.12% by weight of Zr, 0.01 to 0.18% by weight of V, and 0.5% or less by weight of
Zn, is further added to the chemical composition of Si-containing Aℓ-Mg-Cu alloy which
has effect on natural aging retardation.
[0023] To retard the natural aging of the Aℓ-Mg-Cu system alloy, it is preferable that the
alloy contains 1.5 to 3.5% by weight of Mg, 0.3 to 0.7% by weight of Cu, 0.05 to 0.35%
by weight of Si, the ratio of Mg/Cu is in the range of 2 to 7.
[0024] Hereinbelow, the reason why individual components are defined as described above
will be explained. Each content is shown in the terms of weight percentages.
[0025] Mg: Mg is a constitutional element of the Aℓ-Cu-Mg modulated structure of the present
invention. At the Mg content of less than 1.5%, the generation of the modulated structure
is retarded, and the modulated structure cannot be generated, when the alloy sheet
is subjected to baking at a temperature of 120 to 180°C for a baking period of time
from 5 to 40 minutes. Further, at the Mg content of less than 1.5%, ductility is lowered.
On the other hand, when the content exceeds 3.5%, the generation of the modulated
structure is also retarded, and no modulated structure is generated, when the alloy
sheet is subjected to baking at a temperature in the range of 120 to 180°C for a baking
period of time from 5 to 40 minutes. Therefore, it is desirable that the Mg content
is in a range of 1.5 to 3.5%.
[0026] Cu: Cu is a constitutional element of the Aℓ-Cu-Mg modulated structure of the present
invention. At the Cu content of less than 0.3%, the modulated structure cannot be
generated. When the content exceeds 1.0%, corrosion resistance remarkably deteriorates.
Therefore, it is desirable to contain Cu in a range of 0.3 to 1.0%. However, when
the Cu content exceeds 0.7%, the Aℓ-Cu-Mg modulated structure is generated even at
ordinary temperature. As a result, the secular change in strength of the alloy generates.
Therefore, the degree of bake hardening is decreased. More, corrosion resistance deteriorates
in some extent. Hence, it is more desirable the Cu content is in a range of 0.3 to
0.7% taking natural aging problem and corrosion resistance into consideration.
[0027] The ratio of Mg to Cu (Mg/Cu) is desirably in the range of 2 to 7. Within the range,
the modulated structure can be effectively generated.
[0028] Fig. 3 is a graph showing the relationship between the presence or absence of streak
observed in electron beam diffraction grating and the ratio of Mg to Cu. As is apparent
from in Fig. 3, a streak is observed when the ratio of Mg to Cu is in the above mentioned
range.
[0029] Si: Mg is a constitutional element which improves a hardenability by facilitating
generation of the Aℓ-Cu-Mg modulated structure and suppresses natural aging. To perform
the function efficiently, it is desirable that the Si content is 0.05% or more. When
the Si content exceeds 0.6%, the above mentioned modulated structure is generated,
however, at the same time, a GP (1) modulated structure of Mg
2Si is also generated. The GP (1) modulated structure facilitates natural aging which
leads to remarkable increase with time in the strength of the sheets prior to being
subjected to a baking treatment. As a result, the degree of bake hardening is reduced.
Therefore, it is desirable that the Si content is 0.6% or less.
[0030] Fig. 4 shows the effect of the Si content on the degree of bake hardening. Fig. 4
shows the case in which an intermediate tempering treatment is not performed in the
alloy sheet manufacturing process. The degree of bake hardening by the baking treatment
is calculated by subtracting yield strength before the baking treatment from that
of after baking treatment. As is apparent from Fig. 4, a higher degree of hardening
can be obtained within the above mentioned range.
[0031] To retard natural aging without generating the GP (1) modulated structure of Mg
2 Si, it is desirable that the Si content is especially 0.35% or less.
[0032] Fig. 5 shows the effect of the Si content on natural aging and bake hardening property.
As is apparent from Fig. 5, natural aging is retarded when Si content is within the
range of 0.05 to 0.35%, while the value of bake hardening is maintained 5 Kgf/mm
2.
[0033] Elements other than these above mentioned basic elements are also restricted for
the following reasons.
[0034] Sn, In, Cd: These alloy elements are the atoms which strongly bind to frozen vacancies
generated by a quenching treatment performed after a solution treatment. The number
of vacant holes which serve as GPB zone forming sites of the Aℓ-Cu-Mg compound are
reduced, thereby retarding natural aging. However, when the content of each element
is less than 0.01%, the effect of these elements is not obvious. In contrast, when
the content exceeds 0.5%, the effect saturates. That is, the effect is no more produced
in proportion to the content, thereby lowering cost performance.
[0035] Fig. 6 shows the effect of Sn on natural aging. As is apparent from Fig. 6, 0.05%
or more of the Sn content retards natural aging.
[0036] Fe: When Fe is present in a content of 0.50% or more, a coarse crystal is readily
formed with Aℓ, thereby causing deterioration of the formability. Fe also reduces
the content of Si which is effective to form the modulated structure by binding to
Si. Therefore, it is desirable that the Fe content is 0.5% or less. However, since
a small amount of Fe contributes to formability and the effect can not be obtained
when the amount is less than 0.03%, the Fe content is desirably 0.03% or more.
[0037] Ti, B: Ti and B are present in the form of TiB
2, which improves the workability during hot working by making crystal grains of the
ingot fine. Therefore, it is important to add Ti together with B. However, an excess
content of Ti and B facilitates generation of a coarse crystal thereby causing deterioration
of the formability. Therefore, the contents of Ti and B are desirably in the range
such that the effect can be obtained efficiently, that is, the range of 0.005 to 0.15,
and 0.0002 to 0.05%, respectively.
[0038] Mn, Cr, Zr, V: These elements are recrystallization suppressing elements. In order
to suppress abnormal grain growth, these elements may be added in an appropriate amount.
However, these elements have a negative effect on equiaxed formation of the recrystallized
particle, thereby causing deterioration of the formability. Therefore, the content
of these elements should be limited to less than that contained in a conventional
aluminum alloy. Hence, the contents of Mn, Cr, Zr, and V are restricted to 0.01 to
0.50%, 0.01 to 0.15%, 0.01 to 0.12%, and 0.01 to 0.18%, respectively.
[0039] Zn: Zn is an element which contributes to improving strength. However, the content
in excess of 0.5% reduces the degree of bake hardening. To be more specific, in the
Zn content exceeding 0.5%, a modulated structure, which is the stage prior to the
precipitation of the Aℓ-Zn system compound, may be generated. The modulated structure,
however, can be also generated at ordinary temperature and the strength of the alloy
sheet prior to be subjected to baking, remarkably increases with time, thereby decreasing
the degree of bake hardening. Therefore, it is necessary that the content of Zn should
not be exceed 0.5%.
[0040] The other element,
Be may be added up to 0.01%.
Be prevents oxidation at the time of casting, thereby improving castability, hot workability,
and formability of an alloy sheet. However, the
Be content in excess of 0.01% is not preferable because not only the effect is saturated
but also
Be turns into a strong poison to damage the working circumstances at the time of casting.
Therefore the upper limit of the
Be content should be 0.01%.
[0041] Besides the above mentioned elements, inevitable impurities are also contained in
the aluminum alloy sheet as observed in a conventional one. The amount of the inevitable
impurities is not limited as long as it is not ruin the effect of the present invention.
For example, Na and K, if they are present in a content of 0.001%, may not affect
properties of the aluminum alloy.
[0042] Hereinbelow, manufacturing conditions to obtain the aluminum alloy sheet.
[0043] First, an aluminum alloy whose components and composition are defined above is melted
and casted to obtain an ingot by conventional procedure. The ingot is then subjected
to a homogenizing heat treatment at a temperature in the range of 400 to 580°C in
one step or in multiple steps, thereby facilitating a diffusion dissoluting of an
eutectic compound crystallized at a casting process, and reducing local microsegregation.
Further, the homogenizing heat treatment suppresses abnormal growth of crystal grains.
As a result, fine grains of compounds of Mn, Cr, Zr, and V, which perform an important
function in homogenizing the alloy, can be precipitated. However, when the homogenizing
heat treatment is performed at a temperature less than 400°C, the above mentioned
effect could not be sufficiently obtained. When the treatment is performed at a temperature
in excess of 580°C, a eutectic melting would be occurred. Therefore, the temperature
of the homogenizing heat treatment is defined in the range of 400 to 580°C. When the
treatment is performed for the period of time less than one hour at a temperature
in the range mentioned above, the effect could not be sufficiently obtained. On the
other hand, when this treatment is performed over 72 hours, the effect is saturated.
Hence, it is desirable that the reaction time is 1 to 72 hours.
[0044] An ingot completed with the homogenizing treatment is then subjected to a hot rolling
and a cold rolling to obtain a sheet having a predetermined thickness by conventional
procedure. In order to straighten or to adjust surface roughness, 5% or less of leveling,
stretching or skin pass rolling may be performed before or after, or before and after
the following heat treatment.
[0045] After the rolling step, the rolled sheet is subjected to a heat treatment including
heating the sheet up to a temperature in the range of 500 to 580°C at a heating rate
of 3°C/second or more; then keeping the sheet for at most 60 seconds at the temperature
reached or not keeping; and cooling the sheet rapidly to 100°C at a cooling rate of
2°C/second or more.
[0046] The heat treatment is performed in order to intend to dissolve Cu and Mg which are
the constituents of the modulated structure made of the Aℓ-Cu-Mg compound to the alloy
and to obtain the sufficient degree of bake hardening. In this case, when the heating
treatment is performed at 500°C or less, the above mentioned effect could not be sufficiently
obtained. On the other hand, when the temperature exceeds 580°C; when the heating
rate is less than 3°C/second; or when the keeping time exceeds 60 seconds, abnormal
grain growth would be readily occurred in certain grains. Further, it is not preferable
that the cooling rate is less than 2°C/second in view of increasing bake hardening,
since the coarse Aℓ-Cu-Mg compound is precipitated during the cooling step.
[0047] In addition to the steps, it is preferable to perform an intermediate annealing treatment
including heating the sheet at a temperature in a range of 500 to 580°C at a heating
rate of 3°C/second or more; keeping the sheet for at most 60 seconds at the temperature
reached or not keeping; and cooling the sheet to 100°C at a cooling rate of 2°C/second,
after rolling the ingot up to the intermediate thickness.
[0048] Then, the thus obtained sheet is subjected to a cold reduction of 5 to 45%.
[0049] By virtue of the additional step mentioned above, the formation of the modulated
structure is accelerated, thereby increasing the degree of bake hardening.
[0050] Fig. 7 shows the relationship between the intermediate thickness of the sheet to
be subjected to an intermediate annealing treatment and the degree of bake hardening.
The thicknesses of the final sheet were constant values of 1.0 mm. In addition to
the intermediate sheet thickness, the rolling reductions of the cold rolling following
the intermediate annealing step are also described on the abscissa axis. The degree
of bake hardening is calculated by subtracting the yield strength before baking from
that of after the baking. As apparent from Fig. 7, when the intermediate annealing
treatment is performed in the intermediate thickness such that the rolling reduction
of the final rolling step is 5 to 45%, the degree of bake hardening can be as high
as 7 kg/mm
2. When the rolling reduction of the final rolling step is 5% or less, the formability
may deteriorate since the generation of the modulated structure of the Aℓ-Cu-Mg compound
may not be facilitated and the baking hardenability thereof may be low, and further
an abnormal grain growth may be occurred.
[0051] The intermediate tempering condition is the same as that used in the heat treatment
following the rolling step. When the heating rate and the cooling rate are below the
minimum value, a coarse Aℓ-Mg-Cu compound may be precipitated, thereby reducing baking
hardenability.
[0052] The thus obtained aluminum alloy sheet is excellent in hardening property obtained
by baking at low temperature for a short period of time and suitable for use in an
automobile body sheet.
EXAMPLES
[0053] Hereinafter the Examples of the present invention will be described.
Example 1
[0054] An alloy comprising the components in the contents shown in Table 1, was melted,
continuously casted to form ingots. The obtained ingots were subjected to facing.
The ingots were subjected to a 2-step homogenizing heat treatment, first for 4 hours
at 440°C, and second, for 10 hours at 510°C. Then, the ingots were heated to 460°C
and subjected to a hot-rolling to form sheets having thickness of 4 mm. After cooled
at room temperature, the above obtained sheets were subjected to a cold-rolling to
obtain a sheets having thickness of 1.4 mm, followed by performing an intermediate
annealing treatment which includes heating up to 550°C at a heating rate of 10°C/second;
keeping the sheets for 10 seconds at 550°C; and air-cooling compulsorily to 100°C
at a cooling rate of 20°C/second.
[0055] After the sheets were cooled to room temperature, the sheet were subjected to a cold
rolling to form the final sheets having thickness of 1 mm. Note that, the finish temperature
of the hot rolling treatment was 280°C.
[0056] The above obtained sheets of 1 mm in thickness were heated to 550°C at a heating
rate of 10°C/second, kept for 10 seconds, and cooled compulsorily to 100°C at a cooling
rate of 20°C/second.
[0057] After the sheets thus obtained were allowed to age for one week at room temperature,
the sheets were cut off in the predetermined shapes to conduct a tensile test with
respect to both a stretched direction and to a rolled direction according to methods
described in the Japanese Industrial Standard (JIS) No. 5, and to conduct a conical
cup test which was simulated actual press forming according to JIS Z2249 (using test
tool 17 type). The complex formability of overhang and deep drawing was evaluated
as the CCV value (mm). The smaller the CCV value is, the better the formability obtained.
[0058] In order to simulate paint baking following press forming, a heat treatment was carried
out at 170°C for 20 minutes. This treatment corresponds to an actual baking step.
Again, the tensile test was performed in substantially the same condition as in the
above. The test pieces were observed under the microscope.
[0059] These test results are shown in Table 2. The value of the column "bake hardening"
is obtained by subtracting yield strength after the final heat treatment from that
after the heat treatment simulating the actual baking step. The presence or absence
of the streak corresponding to the modulated structure of the Aℓ-Cu-Mg compound was
also shown.
[0060] Alloys Nos. 1 to 15 of Table 1 contain Mg, Cu, and Si, or optional elements such
as Fe, Ti, B, Mn, Cr, Zr, V, and Zn in the range of the present invention adding to
above basic components. On the contrary, in the alloys Nos. 16 to 30 these elements
are not within the range of composition of the present invention. It should be noted,
however, that due to the absence of at least one element selected from the group consisting
of 0.01 to 0.50 % by weight of Sn, 0.01 to 0.50 % by weight of Cd, and 0.01-0.50 %
by weight of In none of the Alloys Nos 1-30 fall within the present invention and
are exemplified merely for illustrative purposes.
[0061] As shown in Table 2, alloy sheets Nos. 1 to 15 show 30% or more of fracture elongation
and a satisfactory CCV value, thereby demonstrating that excellent formability were
obtained.
[0062] Further it was confirmed that the streak corresponding to the modulated structure
of the Aℓ-Cu-Mg compound was generated by baking, and that the alloys possessed the
value of bake hardening as high as 6.5 kgf/mm
2 or more in the terms of yield strength.
[0063] On the other hand, alloy sheets Nos. 16 to 30 shown in Table 2 possessed unsatisfactory
values either in formability or in bake hardening. More specifically, in alloy sheets
Nos. 16, 18, and 20, which contained elements contributing to improvement in bake
hardening, such as Mg, Si, and Cu, any of which was present in a small amount, as
well as in alloy sheets Nos. 17, 19, and 21, which contained Mg, Si, or Cu, any of
which was present in a large amount, the streak could not be observed in an electron
diffraction pattern which is obtained after the baking treatment and the value of
bake hardening thereof was at most 4 kgf/mm
2. Alloy sheet, No. 25, which contained Zn in a large amount showed bake hardening
as low as 2.4 kgf/mm
2. Alloy sheets Nos. 22, 23, 24, 26, 27, 28, and 29, whose contents of Fe, Ti-B, Mn,
Cr, Zr, and V were in the preferred range of the present invention, showed lower formability.
Alloy sheet No. 30, whose ratio of Mg/Cu did not satisfy the range of 2 to 7, showed
the value of bake hardening of 3.6 kgf/mm
2.
Example 2
[0065] As shown in Table 3, alloy sheets Nos. 1' to 15' show 30% or more of fracture elongation
as observed alloys Nos. 1 to 15 of Example 1. It was confirmed that the streak corresponding
to the modulated structure of the Aℓ-Cu-Mg compound was generated by baking, and that
the alloys showed values of bake hardening as high as 5.2 kg/mm
2 or more in the terms of yield strength although the bake hardening was lower than
that of the alloy sheets manufactured by a process including intermediate tempering.
[0066] It was also confirmed that the degree of the bake hardening of Nos. 16' to 30' was
lower than that of Nos. 16 to 30.
Example 3
[0067] Alloy sheets were manufactured using an ingot having a chemical composition corresponding
to No. 1 shown in Table 1 in the condition shown in Table 4. With respect to treatments,
e.g., rolling condition and the like which are not described in Table 4, substantially
the same treatments as in Example 1 were employed. The manufacturing conditions, A
to E in Table 4 are within the range of the present invention, but F to L are not.
[0068] With respect to the thus manufactured alloy sheets, evaluation tests were conducted
in substantially the same manner as in Example 1. The results are also shown in Table
4.
[0069] As shown in Table 4, the alloy sheets manufactured in the conditions of A to E showed
satisfactory formability and bake hardening, however, the alloy sheets manufactured
in the conditions of F to L showed unsatisfactory results of fracture elongation,
formability, and bake hardening.
[0070] When homogenizing temperature or heat treatment temperature was high, the rolling
reduction of the cold rolling following the intermediate annealing was low or the
heating rate of the heating treatment was low as in Comparative Examples F, G, I,
and J, abnormal grain growth occurred, with the result that the fracture elongation
and the formability deteriorated.
[0071] When the rate of the cold reduction following the intermediate annealing was high,
as in the case of H, or when a cooling rate at the time of a solution treatment was
low, as in the case of L, the streak corresponding to the modulated structure of the
Aℓ-Cu-Mg compound was not observed in the electron diffraction pattern, thereby causing
deterioration in bake hardening. Further, when the alloy sheets were kept at low temperature
in the solution treatment, as in the case of K, the formability of the alloy sheets
deteriorated since fracture elongation was low and sufficient bake hardening was not
obtained.
Example 4
[0072] Alloy sheets were manufactured using an ingot having a chemical composition corresponding
to No. 1 of Table 1 in substantially the same condition as A to L of Example 3 except
that the intermediate tempering treatment was not performed. With respect to the thus
obtained alloy sheets, evaluation tests were conducted in substantially the same manner
as in Example 3. The results are shown in Table 5. A' to L' in Table 5 correspond
to A to L in Example 3.
[0073] As shown in Table 5, it was confirmed that the alloy sheets manufactured in conditions
A' to E' were slightly lower in bake hardening than those of A to E of Table 4, but
the value itself was kept high. Further the alloys manufactured in conditions F' to
L' were slightly lower in bake hardening than those of F to L shown in Table 7.
Example 5
[0074] Alloy sheets were manufactured using an chemical composition as the same as that
of No. 1 in Table 1 in condition A' shown in Table 5. The properties of the alloy
sheets obtained by varying the baking condition thereof were evaluated. The results
are shown in Table 6 and Fig. 8.
[0075] As shown in Table 6 and Fig. 8, the streak corresponding to the modulated structure
of the Aℓ-Cu-Mg compound was generated by baking at a temperature in the range of
120 to 180°C for a period of time from 5 to 40 minutes, thereby demonstrating that
the alloy had high bake hardening property.
Example 6
[0076] In Example 6, the alloy sheets containing Sn, In, and Cd as additional elements were
tested.
[0077] Alloy sheets of 1 mm in thickness were manufactured in substantially the same condition
as in Example 1 using the alloys having chemical compositions and the contents shown
in Table 7, and then subjected to the heat treatment in substantially the same condition
as in Example 1.
[0078] After the heat treatment was completed, the alloys were allowed to age at room temperature
for one day and 60 days in order to evaluate natural aging. Further, the tensile test
and the conical cup test were conducted in substantially the same manner as in Example
1 using pieces cut off in the predetermined shape from the alloy sheet. The paint
baking following press forming was simulated in substantially the same manner as in
Example 1, thereby evaluating estimating the bake hardening. The test pieces were
also observed under the microscope.
[0079] These results are shown in Table 8.
[0080] Nos. 31 to 46 contain Mg, Cu, and Si in the contents within the range of the present
invention and further contain at least one selected from the group consisting of Sn,
In, and Cd, or further contain Fe, Ti, B, Mn, Cr, Zr, V, or Zn in the contents within
the present invention. The chemical compositions of Nos. 47 to 61 are not within the
range of the present invention.
[0081] As shown in Table 8, the alloys Nos. 31 to 46 showed 30% or more of fracture elongation
and satisfactory CCV values, thereby demonstrating that excellent formability was
obtained. Also it was confirmed that the streak corresponding to the modulated structure
of the Aℓ-Cu-Mg compound was generated by baking treatment, and that the value of
bake hardening showed as high as 6.4 kgf/mm
2 in terms of yield strength. Furthermore it was confirmed that after being allowed
to age for 60 days at room temperature, and that the alloys increased in the yield
strength by at most 0.5 kgf/mm
2, thereby demonstrating that natural aging was retarded.
[0082] On the other hand, any of formability, bake hardening, and natural aging retardation
of alloys Nos. 47 to 61 was unsatisfactory. For example, Nos. 47, 49, and 51 containing
Mg, Si, or Cu, any of which was present in a small amount, and Nos. 48 and 50 containing
Mg, Si, or Cu, any of which was present in a large amount, the streak was not observed
in an electron diffraction pattern which was obtained after baking treatment and the
bake hardening showed at most 4 kgf/mm
2. Also, alloys Nos. 50, 52, and 55 containing Si, Cu, and Zn in a large amount, respectively
and No. 60 having Sn, In, and Zn in a low content, respectively, increased in yield
strength (5 kgf/mm
2) by being allowed to age for 60 days at room temperature, thereby demonstrating that
natural aging was remarkably progressed.
[0083] As the same as in Example 1, alloys Nos. 53, 54, 56, 57, 58, and 59 whose contents
of Fe, Ti-B, Mn, Cr, Zr, and V were not within the range of the present invention,
showed low formability. Alloy No. 61 whose Mg/Cu ratio was not within the range of
the present invention, showed the value of the bake hardening of 3.7 kgf/mm
2.
Example 7
[0084] Alloy sheets were manufactured using an ingot having the chemical composition of
No. 31 shown in Table 7 in the condition shown in Table 9. With respect to the condition
and the like conditions, e.g., rolling condition and the like which are not described
in Table 9, substantially the same treatment as in Example 6 were employed. The chemical
compositions of alloy sheets M to Q of Table 9 are within the range, but those of
alloy sheets R to X are not.
[0085] Substantially the same evaluation tests as in Example 6 were conducted with respect
to the above obtained alloy sheets. The results are shown in Table 9.
[0086] As shown in Table 9, it was confirmed that alloy sheets M to Q of the present invention
showed satisfactory result of formability and bake hardening, and that sheets R to
X, which did not satisfy the condition of the present invention provided unsatisfactory
result of fracture elongation, formability, and bake hardening.
[0087] For example, when homogenization temperature or heat treatment temperature were high;
the rate of the cold reduction following an intermediate annealing treatment was low;
or the heating rate of the heat treatment was low, as in the case of alloy sheets,
R, S, U, and V, abnormal grain growth appeared, thereby demonstrating that the above
sheets were poor in fracture elongation and formability. When rate of the cold reduction
following the intermediate annealing was high as in the case of alloy sheet T, or
when the cooling rate of the solution treatment was low as in the case of alloy sheet,
X, the streak corresponding to the modulated structure of the Aℓ-Cu-Mg compound was
not observed in an electron diffraction pattern, thereby demonstrating that alloy
sheets T and X were poor in bake hardening property. When the maintaining temperature
of the solution treatment was low as in the case of alloy sheet W, the sheets exhibited
poor formability due to poor elongation, thereby demonstrating that the sheet did
not obtain sufficient bake hardening property.
Example 8
[0088] In Example 8, it was confirmed that the effect of the present invention can be provided
by limiting the contents of Mg, Cu, and Si to 1.5 to 3.5%, 0.3 to 0.7%, and 0.05 to
0.35%, respectively.
[0089] Alloys Nos. 1, 4, and 6 of the above range and Nos. 5 and 7 whose chemical contents
were not in the above range were processed to form the sheet of 1 mm in thickness.
Heat treatment was conducted in substantially the same condition as in Example 1.
[0090] In order to study of influence of the natural aging, the sheets were allowed to age
at room temperature for one day, 30 days, and 90 days after the heat treatment was
completed. The tensile test and the conical cup test were conducted in substantially
the same manner as in Example 1. The results are shown in Table 10.
[0091] As shown in Table 10, alloys Nos. 1, 4, and 6 of above range hardly increased in
yield strength and exhibited satisfactory CCV values even after 90 days aging at room
temperature, thereby demonstrating that natural aging was retarded.
[0092] On the other hand, alloys Nos. 5 and 7, which were not in the above range, increased
in yield strength in proportional to the days of the aging and exhibited poor formability.
[0093] From the results of the above Examples, it is demonstrated that there can be provided
an aluminum alloy sheet and a method of manufacturing the alloy sheet for use in press
forming, having excellent hardening property obtained by baking at low temperature
for a short period of time, and an aluminum alloy sheet and a method of manufacturing
the alloy sheet for use in press forming exhibit no secular change in strength prior
to being subjected to press forming owing to low strength prior to being subjected
to press forming and a natural aging retardation property.
1. Aluminiumlegierungsblech zur Verwendung beim Preßformen, das folgendes aufweist:
a) eine Si-haltige Al-Mg-Cu-Legierung, die 1,5 bis 3,5 Gew.-% Mg, 0,3 bis 1,0 Gew.-%
Cu, 0,05 bis 0,6 Gew.-% Si aufweist,
b) wenigstens ein Element, das aus der Gruppe ausgewählt ist, die besteht aus 0,01
bis 0,50 Gew.-% Sn, 0,01 bis 0,50 Gew.-% Cd und 0,01 bis 0,50 Gew.-% In,
c) fakultativ wenigstens ein Element, das aus der Gruppe ausgewählt ist, die besteht
aus 0,03 bis 0,50 Gew.-% Fe, 0,005 bis 0,15 Gew.-% Ti, 0,0002 bis 0,05 Gew.-% B, 0,01
bis 0,50 Gew.-% Mn, 0,01 bis 0,15 Gew.-% Cr, 0,01 bis 0,12 Gew.-% Zr, 0,01 bis 0,18
Gew.-% V und 0,5 Gew.-% oder weniger Zn, und
d) einen Rest Al und unvermeidliche Verunreinigungen, wobei das Verhältnis Mg/Cu im
Bereich von 2 bis 7 ist,
wobei das Aluminiumlegierungsblech nach dem Ausheizen bei einer Temperatur von 120
bis 180 °C für 5 bis 40 min ein moduliertes Gefüge der Al-Cu-Mg-Verbindung hat, wobei
das modulierte Gefüge im Elektronenbeugungsbild des Legierungsblechs als Intensitätsmarken
in Form von Streifen zwischen den Al-Gitterstellen beobachtet wird.
2. Aluminiumlegierungsblech nach Anspruch 1, wobei die Mg-, Cu- und Si-Komponenten im
Bereich von 1,5 bis 3,5 Gew.-% Mg, 0,3 bis 0,7 Gew.-% Cu und 0,05 bis 0,35 Gew.-%
Si anwesend sind.
3. Verfahren zum Herstellen eines Aluminiumlegierungsblechs zur Verwendung beim Preßformen,
wobei das Blech eine ausgezeichnete Härtungseigenschaft durch Ausheizen bei niedriger
Temperatur für einen kurzen Zeitraum hat, wobei das Verfahren die folgenden Schritte
aufweist:
a) Herstellen eines Aluminiumlegierungsblocks, der 1,5 bis 3,5 Gew.-% Mg, 0,3 bis
1,0 Gew.-% Cu, 0,05 bis 0,6 Gew.-% Si aufweist,
wobei wenigstens ein Element aus der Gruppe ausgewählt ist, die besteht aus 0,01 bis
0,50 Gew.-% Sn, 0,01 bis 0,50 Gew.-% Cd und 0,01 bis 0,50 Gew.-% In,
wobei fakultativ wenigstens ein Element aus der Gruppe ausgewählt ist, die besteht
aus 0,03 bis 0,50 Gew.-% Fe, 0,005 bis 0,15 Gew.-% Ti, 0,0002 bis 0,05 Gew.-% B, 0,01
bis 0,50 Gew.-% Mn, 0,01 bis 0,15 Gew.-% Cr, 0,01 bis 0,12 Gew.-% Zr, 0,01 bis 0,18
Gew.-% V und 0,5 Gew.-.% oder weniger Zn, und
Rest Al und unvermeidliche Verunreinigungen, wobei das Verhältnis von Mg/Cu im Bereich
von 2 bis 7 ist;
b) Homogenisieren des Blocks in einem Schritt oder in einer Vielzahl von Schritten,
durchgeführt bei einer Temperatur innerhalb des Bereichs von 400 bis 580 °C;
c) Herstellen eines Legierungsblechs mit einer gewünschten Blechdicke, indem der Block
einem Warmwalzen und einem Kaltwalzen unterzogen wird; und
d) Unterziehen des Legierungsblechs einer Wärmebehandlung, die umfaßt: Aufheizen des
Blocks bis zu einem Bereich von 500 bis 580 °C mit einer Aufheizrate von 3 °C/s oder
mehr, Halten des Blocks auf der erreichten Temperatur für 0 bis 60 s und Abkühlen
des Blocks auf 100 °C mit einer Abkühlrate von 2 °C/s oder mehr.
4. Verfahren zum Herstellen eines Aluminiumlegierungsblechs nach Anspruch 3, wobei die
Mg-, Cu- und Si-Komponenten im Bereich von 1,5 bis 3,5 Gew.-% Mg, 0,3 bis 0,7 Gew.-%
Cu und 0,05 bis 0,35 Gew.-% Si anwesend sind.
5. Verfahren zum Herstellen eines Aluminiumlegierungsblechs nach Anspruch 3 oder 4, wobei
die Schritte c) und d) durch die folgenden Schritte ersetzt werden:
e) Unterziehen des Blocks von Schritt (b) einem Warmwalzen und einem Kaltwalzen oder
nur einem Warmwalzen, um ein Legierungsblech-Vormaterial zu bilden;
f) Unterziehen des Vormaterials einer Zwischenglühbehandlung, die umfaßt: Aufheizen
des Blocks bis zu einem Bereich von 500 bis 580 °C mit einer Aufheizrate von 3 °C/s
oder mehr, Halten des Blocks auf der erreichten Temperatur für 0 bis 60 s und Abkühlen
des Blocks auf 100 °C mit einer Abkühlrate von 2 °C/s oder mehr;
g) Herstellen eines Legierungsblechs mit einer gewünschten Dicke, indem das Vormaterial
einer Kaltwalzbehandlung mit einer Walzreduktion von 5 von 45 % unterzogen wird; und
h) Unterziehen des Legierungsblechs einer Wärmebehandlung, die die folgenden Schritte
umfaßt: Aufheizen des Blocks bis zu einem Bereich von 500 bis 580 °C mit einer Aufheizrate
von 3 °C/s oder mehr, Halten des Blocks auf der erreichten Temperatur für 0 bis 60
s und Abkühlen des Blocks auf 100 °C mit einer Abkühlrate von 2 °C/s oder mehr.
1. Feuille en alliage d'aluminium pour une utilisation en formage à la presse, comprenant:
a) un alliage Al-Mg-Cu contenant du Si, comprenant 1,5 à 3,5% en poids de Mg, 0,3
à 1,0% en poids de Cu, 0,05 à 0,6% en poids de Si,
b) au moins un élément choisi parmi le groupe constitué de 0,01 à 0,50% en poids de
Sn, 0,01 à 0,50% en poids de Cd, et 0,01 à 0,50% en poids de In,
c) éventuellement, au moins un élément choisi parmi le groupe constitué de 0,03 à
0,50% en poids de Fe, 0,005 à 0,15% en poids de Ti, 0,0002 à 0,05% en poids de B,
0,01 à 0,50% en poids de Mn, 0,01 à 0,15% en poids de Cr, 0,01 à 0,12% en poids de
Zr, 0,01 à 0,18% en poids de V, et 0,5% ou moins en poids de Zn, et
d) un complément en Al et en impuretés inévitables, où le rapport Mg/Cu est dans le
domaine de 2 à 7, ladite feuille en alliage d'aluminium, après cuisson à une température
de 120°C à 180°C pendant 5 à 40 minutes, ayant une structure modulée du composé Al-Mg-Cu,
ladite structure modulée étant observée dans le diagramme de diffraction électronique
de la feuille en alliage en tant que marques d'intensité sous la forme de raies entre
les sites du réseau d'Al.
2. Feuille en alliage d'aluminium selon la revendication 1, dans laquelle les composants
Mg, Cu et Si sont présents dans le domaine de 1,5 à 3,5% en poids de Mg, 0,3 à 0,7%
en poids de Cu et 0,05 à 0,35% en poids de Si.
3. Procédé de fabrication d'une feuille en alliage d'aluminium pour une utilisation en
formage à la presse, ladite feuille ayant une excellente propriété de durcissement
par cuisson de courte durée, à basse température ledit procédé comprenant les étapes
de:
a) préparation d'un lingot en alliage d'aluminium comprenant 1,5 à 3,5% en poids de
Mg, 0,3 à 1,0% en poids de Cu, 0,05 à 0,6% en poids de Si,
au moins un élément choisi parmi le groupe constitué de 0,01 à 0,50% en poids de Sn,
0,01 à 0,50% en poids de Cd, et 0,01 à 0,50% en poids de In,
éventuellement, au moins un élément choisi parmi le groupe constitué de 0,03 à 0,50%
en poids de Fe, 0,005 à 0,15% en poids de Ti, 0,0002 à 0,05% en poids de B, 0,01 à
0,50% en poids de Mn, 0,01 à 0,15% en poids de Cr, 0,01 à 0,12% en poids de Zr, 0,01
à 0,18% en poids de V, et 0,5% ou moins en poids de Zn, et
un complément en Al et en impuretés inévitables, où le rapport Mg/Cu est dans le domaine
de 2 à 7;
b) homogénéisation du lingot en une étape ou en plusieurs étapes, réalisée à une température
dans le domaine de 400 à 580°C;
c) préparation d'une feuille en alliage ayant une épaisseur de feuille souhaitée en
soumettant le lingot à un laminage à chaud et un laminage à froid; et
d) soumission de la feuille en alliage à un traitement thermique comprenant le chauffage
du lingot jusqu'à un domaine de 500 à 580°C à une vitesse de chauffage de 3°C/seconde
ou plus, le maintien de celui-ci à la température atteinte pendant 0 à 60 secondes,
et le refroidissement de celui-ci jusqu'à 100°C à une vitesse de refroidissement de
2°C/seconde ou plus.
4. Procédé de fabrication d'une feuille en alliage d'aluminium selon la revendication
3, dans laquelle les composants Mg, Cu et Si sont présents dans le domaine de 1,5
à 3,5% en poids de Mg, 0,3 à 0,7% en poids de Cu et 0,05 à 0,35 en poids de Si.
5. Procédé de fabrication d'une feuille en alliage d'aluminium selon la revendication
3 ou 4, dans lequel les étapes c) et d) sont remplacées par les étapes suivantes:
e) soumission du lingot de l'étape (b) à un laminage à chaud et un laminage à froid
uniquement pour former un stock de feuille en alliage;
f) soumission du stock à un traitement de recuit intermédiaire comprenant le chauffage
du lingot jusqu'à un domaine de 500 à 580°C à une vitesse de chauffage de 3°C/seconde
ou plus, le maintien de celui-ci à la température atteinte pendant 0 à 60 secondes,
et le refroidissement de celui-ci jusqu'à 100°C à une vitesse de refroidissement de
2°C/seconde ou plus;
g) préparation d'une feuille en alliage ayant une épaisseur souhaitée en soumettant
le lingot à un traitement de laminage à froid avec une réduction de laminage de 5
à 45%; et
h) soumission de la feuille en alliage à un traitement thermique comprenant les étapes
de chauffage du lingot jusqu'à un domaine de 500 à 580°C à une vitesse de chauffage
de 3°C/seconde ou plus, maintien de celui-ci à la température atteinte pendant 0 à
60 secondes, et refroidissement de celui-ci jusqu'à 100°C à une vitesse de refroidissement
de 2°C/seconde ou plus.